The present invention concerns a piston for a damping device (2000), in particular for doors or windows, wherein the piston comprises a first half-piston (2510) and a second half-piston (2511), wherein the piston is configured for use with a first half-cylinder (2410) and a second half-cylinder (2420), wherein a first volume (2430) is included between the first half-piston (2510) and the first half-cylinder (2410), wherein a second volume (2440) is included between the second half-piston (2511) and the second half-cylinder (2420), and wherein the piston (2500) is provided with a hole (2550) for the passage of a fluid (1210) between the first volume (2430) and the second volume (2440). The invention furthermore concerns a damping device and a damped return device comprising the piston.

A supporting member includes: a rotatable spindle supported in a first housing; a cylindrical first guide fixed in a second housing, and guiding a relative movement of the spindle in an axial direction; a second guide fixed in the first housing, having an inner diameter larger than a first guide's outer diameter, and relatively movable in the direction to the first guide; and a nut being a stepped shaft-like member including an insertion portion inserted into the first guide, a protruding portion protruded from the first guide, and a narrow portion provided therebetween. The first guide includes a caulking portion to the nut at an opening end. The caulking portion includes a portion extending to intersect in the direction along a step between the insertion portion and the narrow portion, and another portion parallel to the direction along an outer circumferential surface of the narrow portion.

A vehicle door assembly includes a door module and a door panel. The door module has a back plate with a periphery bearing attachment orifices defining a base plane. At least one guide rail extends in a rail direction in a rail plane offset from the base plane and has a connected edge and a free edge. The connected edge is attached to the back plate, and the free edge is shaped for slidably attaching a carrier plate for a window. The guide rail vertically protrudes beyond the periphery of the back platen. A void in the rail plane intersects a trajectory of the connected edge. The void provides access through the rail plane to the periphery of the back plate, wherein an attachment orifice is disposed in the void. The door panel has a central hole and attachment openings aligned with the attachment orifices of the door module.

A dampened hinge assembly has a male leaf and a female leaf. The female leaf has spaced apart first and second end barrels coaxially rotating with respect to a central barrel of the male leaf therebetween. An axial shaft is fixed to the second end barrel of the female leaf at a proximal end of the axial shaft. The axial shaft has a distal helicoidally threaded spindle. A compression gear having a helicoidally threaded bore matching the helicoidal thread of the spindle displaces towards the first end barrel when the leaves move into alignment and towards the second end barrel when the leaves move out of alignment. The dampened hinge assembly may be reconfigured to provide soft closure, end-of-range soft closure and/or backcheck damping.

To provide a holder-equipped window glass capable of increasing the quality and productivity and capable of preventing breakage of the window glass to be caused by attachment of the holder, and a process for its production. A holder main body 18 is an integrally molded product comprising an inner layer portion 26 and an outer layer portion 28. The inner layer portion 26 is constructed to be U-shaped in cross section to clamp a part of a lower edge 12B of a window glass 12 in the thickness direction of the lower edge 12B. Further, the outer layer portion 28 is located outside the inner layer portion 26, is made of a material harder than the inner layer portion 26 and is constructed to be U-shaped in cross section. This outer layer portion 28 is provided with a connecting portion 16. This connection portion 16 is projecting in a direction departing form the lower edge 12B of the window glass 12.

Door operator systems are described herein that include the use of an adaptor. It should be understood that the adaptor may be utilized in order to operatively couple separate door operator assemblies together in a double door operator system. The adaptor may include control components (e.g., switches, buttons, toggles, levers, or the like) that are used to turn the door operator system on and off. While the adaptor may be used to operatively couple two separate door operator assemblies together to form a double door operator system, the adaptor may also be used within a single door operator system. Furthermore, with respect to double door operator systems, the system may also utilize a back plate assembly comprising two or more separate back plates (e.g., two or more back plate portions).

Disclosed is a new compact clamp for sliding glass doors, which includes two jaws, left jaw and right jaw. One of the jaws has a damper formed by a double-effect damper with gas and oil technology, using a cylinder containing a front gas chamber and a rear gas chamber which are located at the ends of the cylinder, and a central oil tank, the gas chambers and the oil tank being separated by a blind piston and an annular piston, which are both leak tight. In the central oil tank is disposed a non-leak tight damping piston that is connected to a rod of the damper and divides the tank into two oil chambers.

An integrated module as a window regulator assembly including: a carrier panel for mounting to a frame of a vehicle closure panel; at least one rail on the carrier panel, the rail associated with at least one cable guide in conjunction with a regulator carriage, the regulator carriage for coupling to a window of the closure panel; a drive mechanism on the carrier panel, the drive mechanism for operating the regulator carriage along a track of the rail; a cable assembly coupling the regulator carriage to the drive mechanism via the cable guide, the cable assembly including a conduit connected at one end to the rail and connected at another end to the drive mechanism, the conduit containing a cable element slideably received within the conduit; wherein the cable element is unsheathed from the conduit where the cable element is in contact with the cable guide.

A vehicle door assembly includes a door module and a door panel. The door module has a back plate with a periphery bearing attachment orifices defining a base plane. At least one guide rail extends in a rail direction in a rail plane offset from the base plane and has a connected edge and a free edge. The connected edge is attached to the back plate, and the free edge is shaped for slidably attaching a carrier plate for a window. The guide rail vertically protrudes beyond the periphery of the back platen. A void in the rail plane intersects a trajectory of the connected edge. The void provides access through the rail plane to the periphery of the back plate, wherein an attachment orifice is disposed in the void. The door panel has a central hole and attachment openings aligned with the attachment orifices of the door module.

A slide door support device supports a slide door that opens and closes a door opening formed on a side surface of a vehicle body. The slide door support device includes first and second lower rails, an upper rail, and lower and upper guide units. The upper rail includes a straight portion extending to a vehicle front, and a curved portion curved so as to extend inward in a vehicle width direction as a position shifts from a front end of the straight portion to the vehicle front. The upper guide unit includes first and second upper guide rollers that move along the upper rail, an upper load roller rolling on a rolling surface that extends along the upper rail, and an upper rotational arm connected so as to be rotatable relative to the slide door and supporting the first and second upper guide rollers and the upper load roller.